Physics 22000 General Physics Lecture 20 - Fluids Fall 2016 Semester Prof. Matthew Jones 1 Second Midterm Exam Wednesday, November 16 th, 8:00-9:30 pm Location: Elliot Hall of Music -ELLT 116. Covering material in chapters 6-10 Multiple choice, probably about 25 questions, 15 will be conceptual, 10 will require simple computations. A formula sheet will be provided. You can bring one page of your own notes. I put a couple exams from previous years on the web page. 2 3 1
Pascal s Second Law Relation between pressure and force: = 4 Buoyant Force 5 Buoyant Force 6 2
The magnitude of the force of fluid on a submerged object The force exerted by the fluid pushing up on the bottom is greater than the force exerted by the fluid pushing down on the top of the block. 7 The magnitude of the force of fluid on a submerged object To calculate the magnitude of the upward buoyant force exerted by the fluid on the block, we use Pascal s second law to determine the upward pressure of the fluid on the bottom surface of the block, compared to the downward pressure of the fluid on the top surface of the block: = + = + = + 8 Archimedes Principle: Buoyant force 9 3
Archimedes Principle: Buoyant force 10 Example Suppose your mass is 70.0 kg and your density is 970 kg/m 3. If you could stand on a scale in a vacuum chamber on Earth's surface, the reading of the scale would be mg = (70.0 kg)(9.80 N/kg) = 686 N. What will the scale read when you are completely submerged in air of density 1.29 kg/m 3? 11 Example Pretend for a moment that you are Archimedes, who needs to determine whether a crown made for the king is pure gold or some less valuable metal. From Table 10.1, you know that the density of gold is 19,300 kg/m 3. You find that the force that a string attached to a spring scale exerts on the crown is 25.0 N when the crown hangs in air and 22.6 N when the crown hangs completely submerged in water. Is the crown made of gold? 12 4
Buoyancy 13 Application: submarines A submarine's density increases when water fills its compartments. With enough water in the compartments, the submarine's density is greater than that of the water outside, and it sinks. When the water is pumped out, the submarine's density decreases. With enough air in the compartments, its density is less than that of the outside water, and the submarine rises toward the surface. 14 Example An empty life raft of cross-sectional area 2.0 m x 3.0 m has its top edge 0.36 m above the waterline. How many 75-kg passengers can the raft hold before water starts to flow over its edges? The raft is in seawater of density 1025 kg/m 3. 15 5
Stability of ships A challenge to building watercraft is to maintain stable equilibrium for the ship, allowing it to right itself if it tilts to one side due to wind or rough seas. The center-of-gravity of the ship is always at the same location, determined by its distribution of mass. The center-of-buoyancy moves, depending on which parts of the hull are below the water line. These two forces produce a torque about an imaginary point called the metacenter 16 Stability of Ships The buoyant force always points through the metacenter, so it accounts for no torque on the ship. The force of gravity produces a torque about the metacenter that can either right the ship (stable) or cause it to tip more (unstable). 17 Hot Air Balloons Using hot air, balloonists can adjust the average density of the balloon (e.g., the balloon's material, people, equipment) to match the density of air so that the balloon can float at any location in the atmosphere (up to certain limits). A burner under the opening of the balloon regulates the temperature of the air inside the balloon and hence its volume and density. This allows control over the buoyant force that the outside cold air exerts on the balloon. 18 6
Effects of Altitude on Humans Partial pressure is the contribution to the total pressure due to one species of gas particle. The pressure of atmospheric air decreases as one moves higher and higher in altitude. 19 Effects of Altitude on Humans Between 4600 m and 6000 m, heart and breathing rates increase dramatically, and cognitive and sensory function and muscle control decline. Between 6000 m and 8000 m, climbers undergo critical hypoxia, characterized by rapid loss of muscular control and loss of consciousness. 20 SCUBA Diving Scuba divers breathe compressed air. While moving slowly downward, a diver adjusts the pressure outlet from the compressed-air tank to accumulate gas from the cylinder into her lungs, increasing the internal pressure to balance the increasing external pressure. If a diver returns too quickly to the surface, the great gas pressure in the lungs can force bubbles of gas into the bloodstream. This gradual process is called decompression. 21 7